https://orcid.org/0000-0002-2894-8018
Figures
Abstract
Background
The World Health Organization (WHO) declared coronavirus disease 2019 (COVID-19) a global pandemic on 11th March, 2020. In Ethiopia, more than 90,490 and 1,300 confirmed cases and deaths were reported by the Federal Ministry of Health at the time of writing up this project. As health care providers are frontline workers managing the COVID-19 pandemic, this systematic review and meta-analysis aimed to assess the pooled level of knowledge, attitude, and practice towards COVID-19 among health professionals in Ethiopia.
Methods
PubMed, Google Scholar, Excerpta Medica database (EMBASE), Cochrane Library, Web of Science, and African Journal of Online (AJOL) were searched. The data were extracted using Microsoft Excel and analyzed using STATA version 14. Publication bias was checked by funnel plot and more objectively through Egger’s regression test, with P < 0.05 considered to indicate potential publication bias. The heterogeneity of studies was checked using I2 statistics. Pooled analysis was conducted using a weighted inverse variance random-effects model. Subgroup analysis was done related to geographic region and time. A leave-one-out sensitivity analysis was also employed.
Result
A total of 11 studies with 3,843 study participants for knowledge, eight studies with 2,842 study participants for attitude and 10 studies with 3, 435 study participants for practice were used to estimate the pooled level of good knowledge, positive attitude and poor practice among health professionals. The overall estimated good level of knowledge, positive attitude and poor practice towards COVID-19 was found to be 79.4% (95% CI: 73.5%-85.2%; I2 = 96%), 73.7% (95%CI: 63.09%-84.4%; I2 = 98.3%) and 40.3% (95%CI: 31.1%-49.6%; I2 = 97.1%) respectively.
Conclusion
Study findings showed that there were significant gaps in COVID-19 related knowledge, attitude and practice with respect to World Health Organization recommendations on COVID-19 management and personal protection practices. This study therefore recommends that institutions provide with immediate effect accurate and up-to-date information on COVID-19 and training that encourages improved knowledge, attitude and practice to mitigate this pandemic.
Citation: Lake EA, Demissie BW, Gebeyehu NA, Wassie AY, Gelaw KA, Azeze GA (2021) Knowledge, attitude and practice towards COVID-19 among health professionals in Ethiopia: A systematic review and meta-analysis. PLoS ONE 16(2): e0247204. https://doi.org/10.1371/journal.pone.0247204
Editor: Raffaele Serra, University Magna Graecia of Catanzaro, ITALY
Received: October 28, 2020; Accepted: February 2, 2021; Published: February 19, 2021
Copyright: © 2021 Lake et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the paper and its Supporting information files.
Funding: The author(s) received no specific funding for this work.
Competing interests: The authors have declared that no competing interests exist.
Abbreviations: CI, Confidence Interval; COVID-19, Corona Virus Disease; DARE, Database of Abstracts of Review of Effects; Dr, Doctor; EMBASE, Excerpta Medica database; FMOH, Federal Ministry of Health; JBI, The Joanna Briggs Institute; KAP, Knowledge Attitude and Practice; PRISMA, Preferred Reporting Items for Systematic Review and Meta-Analysis; SNNP, South Nations Nationalities and Peoples Region; WHO, World Health Organization
Introduction
A cluster of atypical pneumonia cases was reported to the World Health Organization (WHO) in Wuhan, China, on 31st December 2019 [1]. The name given to this disease was Corona Virus Disease-19 (COVID-19). On March 11, 2020, WHO declared that the disease was a global pandemic [2]. At the time of writing (21th October 2020), COVID-19 had spread to 217 countries and territories and accounted for 41,053,557 confirmed cases of COVID-19 and 1,129,775 deaths. In Ethiopia, there were 90,490 confirmed cases and 1,371 deaths [3]. COVID-19 is a new emerging respiratory disease caused by a single-strand, positive-sense ribonucleic acid (RNA) virus called Severe Acute Respiratory Syndrome Corona Virus-2 (SARS-CoV-2) [4].
There is no known cure for this infection and at the time of writing there were no vaccines available for routine use. The main intervention is the use of preventive measures as recommended by experts which include: use of face masks, wearing gloves, frequent hand washing, avoiding frequent exposure to sensitive areas, keeping physical distance, and avoidance of touching the nose, mouth, and eye with contaminated hands or other contaminated materials [5]. Health care professionals, because of close care needed to look after infected patients, are at serious risk of infection [6].
The World Health Organization (WHO) has issued a number of guidelines on COVID-19 to various sectors of society, and has provided a range of education and training materials to health care workers (HCWs) to increase their awareness and preparedness for COVID-19 control and prevention [7]. While HCWs are at high risk of infection because of working with infected patients in overcrowded hospitals, that in resource-limited settings include a lack of isolation rooms, it is possible that they also have inadequate awareness of infection prevention practices [8]. Incorrect attitudes and poor practices may directly increase the risk of infection among HCWs [9].
Although HCWs represent less than 3% of the population in most countries, especially in low- and middle-income countries, 14% of COVID-19 victims are HCWs, according to the World Health Organization report [10]. The number could rise as much as 35% in some countries. There are still questions about access to information and the quality of information, and it is often difficult to ascertain whether HCWs are infected in the workplace or in the area where they live [10]. The published literature suggests that lack of knowledge and misunderstandings among HCWs leads to delayed diagnosis, spread of disease and poor infection control practice. Several thousand HCWs have already been infected, mainly in China [6]. Preventing nosocomial transmission of this communicable disease is therefore a priority.
To our knowledge, there are only a few studies on Knowledge, Attitude and Practice (KAP) with respect to COVID-19 among HCWs in Ethiopia, and these have shown significant differences in KAP between the various regions of the country. A review done by Samuel SC et al showed that disease transmission increased because the population was reluctant to implement directives from the government [11]. However, this study did not provide a compressive estimation of KAP to COVID-19 among health professionals. We therefore conducted this systematic review and meta-analysis to provide an estimate of KAP with respect to COVID-19 among Ethiopian HCWs for the purpose of improving program planning and interventions focused on the prevention and control of this global pandemic.
Methods
Searching strategy and source of information
This study was conducted to estimate the pooled level of KAP towards COVID 19 among HCWs in Ethiopia. We checked the DARE database (http://www.library.UCSF.edu) and the Cochrane library to ensure this had not been done before and to avoid duplication. We also checked whether there was any similar ongoing systematic review and meta-analysis in the PROSPERO database ((PROSPERO 2017:CRD42017074407); Available from http://www.Crd.york.ac.uk/ PROSPERO_REBRANDING/ display record. asp? ID = CRD42017074407. These checks reassured us that there had been no previous similar studies undertaken.
All relevant and published researches in the following databases; PubMed, Google Scholar, Excerpta Medica database (EMBASE), Cochrane Library, Web of Science, and African Journal of Online (AJOL) were searched. We reviewed grey literature using Google. Unpublished studies were sought from the official website of an international and/or local organization or university.
The following core search terms or phrases were used; knowledge, awareness, attitude, perception, practice, pandemic, COVID-19, SARS CoV-2, coronavirus, health professional and health care provider. Search terms were pre-defined to allow a complete search strategy that included all-important studies. All fields within records and MeSH (Medical Subject Headings) and Boolean operators were used to search in the advanced PubMed search engine.
Notably, to fit with the advanced PubMed database the following search strategy was developed using different Boolean operators; ((((((Knowledge[tw] OR Awareness[tw] OR attitude[tw] OR perception[tw] OR practice[tw])) OR ("Health Knowledge, Attitudes, Practice"[Mesh] OR "Practice Management, Veterinary"[Mesh] OR "Knowledge Discovery"[Mesh] OR "Knowledge Management"[Mesh] OR "Practice Patterns, Nurses‴[Mesh] OR "Knowledge"[Mesh]))) AND (((Pandemic[tw] OR COVID-19[tw] SARS CoV-2[tw] OR corona virus[tw])) OR ("COVID-19 vaccine" [Supplementary Concept] OR "pediatric multisystem inflammatory disease, COVID-19 related" [Supplementary Concept] OR "COVID-19 serotherapy" [Supplementary Concept] OR "COVID-19 diagnostic testing" [Supplementary Concept] OR "ORF7b protein, SARS-CoV-2" [Supplementary Concept] OR "ORF3a protein, SARS-CoV-2" [Supplementary Concept] OR "ORF1ab polyprotein, SARS-CoV-2" [Supplementary Concept] OR "nucleocapsid protein, Coronavirus" [Supplementary Concept] OR "spike protein, SARS-CoV-2" [Supplementary Concept]))) AND (((Health care workers[tw] OR health professional [tw])) OR ("Education, Public Health Professional"[Mesh] OR "Allied Health Personnel"[Mesh]))) AND Ethiopia[tw]. We reviewed studies that assessed KAP on COVID-19 through face to face interviews, self-administered questionnaires or electronically administered structured questionnaires among HCWs.
Measurements of KAP
Knowledge.
Knowledge was assessed based on 16 questions about COVID-19 that included the causative agent, clinical signs, symptoms, mode of transmission, treatment and vaccine availability and mechanisms of prevention. Knowledge was defined as good if the respondents scored above the mean level.
Reporting
The results of this review were reported in line with the Preferred Reporting Items for Systematic Review and Meta-Analysis statement (PRISMA) guideline [12].
Eligibility criteria
All observational studies on KAP towards COVID-19 were considered for this study. Those studies about KAP among HCWs which were published in English were included and there was no restriction on study period or type of HCW. The level of good knowledge, positive attitude and poor practice was calculated using the data presented in the studies. Papers were excluded if they were: review articles, studies reporting confused data or with probable errors, studies without any information on the country and studies which were not able to fully access. An attempt was made to contact the corresponding authors using the email address or phone number as provided in the published articles.
Study selection and extraction
Retrieved articles were exported to the reference manager software, Mendeley Desktop, and this was used to remove duplicate studies. Three independent reviewers screened the title and abstract. Any disagreement was handled based on established article selection criteria. Data were extracted using a standardized data extraction format prepared in Microsoft Excel by two independent reviewers. Any discrepancy during extraction was solved through discussion. The name of the first author, study area and region, the study month and year, the study design, year of publication, study population, sample size, response rate and level of good knowledge, positive attitude and poor practice were collected.
Quality assessment
Three independent authors appraised the quality of the studies. The Joanna Briggs Institute (JBI) quality appraisal checklist was used [13]. When there was disagreement, all three authors discussed and resolved the issue. The critical appraisal checklist had 8 parameters with options of “yes, no, unclear and not applicable.” The quality parameters included the following questions: (1) Were the criteria for inclusion in the sample clearly defined?, (2) Were the study subjects and the setting described in detail?, (3) Was the exposure measured in a valid and reliable way?, (4) Were objective, standard criteria used for measurement of the condition?, (5) Were confounding factors identified?, (6) Were strategies to deal with confounding factors stated?, (7) Were the outcomes measured in a valid and reliable way?, and (8) Was an appropriate statistical analysis used?. Studies were considered low risk if there was a score of 50% and above of the quality assessment indicators.
Statistical analysis
The data were extracted using Microsoft Excel and analyzed by using STATA version 14 statistical software (stataCorp LP, 4905 Lakeway Drive, College Station, TX 77845, USA). Publication bias was checked by funnel plot and more objectively through Begg and Egger’s regression tests, with P < 0.05 considered to indicate potential publication bias [14, 15]. The presence of significant between-study heterogeneity was assessed using the Cochrane Q statistic. I2 was used to quantify between-study heterogeneity, in which a value of 0%, 25%, 50%, and 75% indicated no, low, medium, and increased heterogeneity, respectively [16]. A forest plot was used to visualize the presence of heterogeneity. Since we found a high level of heterogeneity, we used a random-effect model for analysis to estimate Der Simonian and Laird’s pooled effect. Subgroup analysis was done by stud region and month. A leave-one-out sensitivity analysis was employed to see the effect of a single study on the overall meta-analysis estimate. The results were presented in the form of text, tables and figures.
Results
Search outcomes
There were 580 articles retrieved using the electronic search. Of these articles, 229 were excluded due to duplication and 16 articles were fully accessed and assessed for qualification. Eventually, 11 articles met the eligibility criteria and were included in the final meta-analysis. Among those 11 eligible articles, seven of them assessed all KAP characteristics towards COVID-19 (Fig 1).
Characteristics of included studies
Eleven articles which assessed knowledge, 10 which assessed practice and 8 which assessed attitude, all of which fulfilled the inclusion criteria, were included in this systematic review and meta-analysis. All studies had a low risk during the quality assessment. Three studies were conducted in the Amhara region [17–19], two in Addis Ababa [20, 21], one in Oromia [22], one in Tigray [23], one in SNNP [24] and one in Harari [25]. The other two articles on KAP and COVID-19 were nationwide studies [26, 27].
All studies were conducted in 2020 from February to June. All studies employed a cross-sectional study design using a face-to-face or electronically administered questionnaire. The sample size ranged from 166 to 532, and the response rate ranged from 84.3% to 100%. The highest level of good knowledge (93.3%) was recorded in a study from Oromia region and the lowest (53.2%) was recorded in a study conducted in Addis Ababa. There was a high level of poor practice recorded in a study done in Addis Ababa which was 70.2% (Table 1).
Publication bias
Publication bias was assessed using a funnel plot and the Egger and Begg regression test at P<0.05. There was statistical evidence of publication bias for a good level of knowledge. A funnel plot showed some asymmetrical distribution, the Begg and Egger tests were statistically significant with P-values = 0.013 and = 0.027 respectively (Fig 2). There was statistical evidence of publication bias for positive attitude. A funnel plot showed some asymmetrical distribution, the Begg and Egger tests were statistically significant with P-values = 0.0063 and = 0.019 respectively (Fig 3). There was statistical evidence of publication bias for poor practice using a funnel plot and the Egger, and Begg regression test (Fig 4).
Level of knowledge, attitude and practice towards COVID-19
The estimated overall level of good knowledge, positive attitude and poor practice in Ethiopia is presented in a forest plot (Figs 5–7). Using the random-effect model, an overall good level of knowledge was found in 79.4% (95% CI: 73.5%-85.2%; I2 = 96%). The pooled estimated level of positive attitude towards COVID-19 was found in 73.73% (95%CI: 63.0%-84.4%; I2 = 98.3%). The estimated level of poor practice towards COVID-19 among health professionals was found in 40.3% (95%CI: 31.1%-49.6%; I2 = 97.1%).
A leave-out-one sensitivity analysis
A leave-out-one sensitivity analysis was done to evaluate the effect of each study on the pooled level of good knowledge, positive attitude and poor practice by excluding each study step-by-step. The results showed that the excluded study did not bring any significant change to the estimated level of good knowledge, positive attitude and poor practice respectively (Table 2).
Subgroup analysis
The subgroup analysis based on the study region and month showed that the level of good knowledge was found in 70.2% in Addis Ababa and 76.1% in Amhara. The level of good knowledge among health professionals was found to be 67.2% and 84.3% in March 2020 and June 2020 respectively. For attitude and practice, 82.4% of study participants in Addis Ababa had a positive attitude towards COVID-19 but 51.2% of HCWS in Addis showed poor practice against COVID-19. Poor practice was higher in June 2020(50.4%) compared to April (35.2%) (Table 3).
Discussion
Ethiopia is one of the most affected countries in East Africa for C0VID-19 and the disease is increasing in the population day by day. When the disease was first recognized in the country, the government declared a five-month state of emergency and established a national COVID-19 response taskforce aimed at mobilizing resources to mitigate transmission of the virus [28]. HCWs were at the forefront of trying to protect themselves and the population from infection [29].
Because of the limited available literature, we conducted this systematic review and meta-analysis to understand better the KAP among HCWs in Ethiopia. We included all available studies conducted between April and June 2020 using a variety of different search engines and were also able to undertake a sub-group analysis assessing the pattern of COVID-related KAP by geographical distribution and by time.
The study showed a generally good knowledge amongst HCWs varying from about 50–90% with a pooled average of nearly 80%. This finding is consistent with a previous study done by Akshaya and his colleagues [30]. The subgroup analysis showed that HCWs from the Amhara region were more knowledgeable compared with those from the Ethiopian capital, Addis Ababa and were more knowledgeable in June compared with March. The latter finding is not surprising and relates to the start of the outbreak in Ethiopia which was in March when there was little information available about the new disease. Over the next few months, the government and other stakeholders released information and guidelines about COVID-19 and front-line experience was also gained. Differences in socioeconomic and educational status and study settings may have also influenced the results.
About three quarters of HCWs also had a positive attitude about the WHO recommendations aimed at mitigating the spread of COVID-19. Positive attitudes were more common in Addis Ababa than in the Amhara region, and this might be due to more exposure to the disease in the capital city. In contrast, positive attitudes decreased between March and June which might have been due to front-line worker experience of difficulties in personal protective measures and the increasing realization that COVID-19 was a serious new infection with considerable morbidity and mortality. The links to faith may also have increased during this time and these may have supplanted the acceptance of WHO recommendations.
The pooled level of poor practice for protective measures against COVID-19 was low at 40%. This was relatively lower than that found in a previous study Bhagavathula and his colleagues [30]. The reasons for this are unclear but may have to do with protective mechanisms conflicting with normal lifestyles, especially amongst the poorer sectors of the population. Ethiopia is a poor country with the majority of its population engaged in hand-to-mouth existence and preventive measures such as home lockdowns are not easily accepted. Furthermore, Ethiopians have strong social ties in which hospitality, eating, and drinking together is a long-standing tradition—this too rides uncomfortably with home lockdowns.
In our study, the variation between studies resulted in a significant between-study heterogeneity. To assess this further, we used a random-effect model as well as a leave one-out-one sensitivity analysis. The results showed that the estimated pooled level of good knowledge, positive attitude and poor practice was robust and not dependent on a single study. We assessed the possible source variability by sub-group analysis using study month and region. The high heterogeneity might be due to differences in the sample population between studies and the short study period for this new emerging virus.
Strength and limitation of the study
The strengths of the study included the comprehensive search strategy through the different datasets to estimate the national level of knowledge, attitude, and practice towards COVID-19, the involvement of more than one assessor in the quality evaluation and the use of the appraisal process using JBI-MAStARI. The study also had some limitations. These included the fact that measurements for the level of knowledge, attitude and practice were taken from each primary study and operational definitions may have differed between the studies. The absence of a similar previous study makes it difficult to compare our findings with other findings. Finally, our search strategy found limited studies especially no studies from Dire Dawa, Afar, Gambella, Sidama and Benishangul-Gumuz regions and this calls into question the national representativeness of our study.
Conclusion
Our systematic review and meta-analysis showed that there was a significant gap in knowledge, attitude and practice concerning COVID-19 amongst HCWs in Ethiopia. This is important information and requires that the country step up the provision of accurate and up-to-date information on COVID-19 through the relevant institutions and institute better training and education. Further research is required to determine the KAP of HCWs in other regions of the country and more information about why these gaps in KAP still exist.
Acknowledgments
We would like to thank the authors of the primary studies included in this systematic review and meta-analysis. We also have a special thank for Professor Anthony D Harries for his critical review of the manuscript.
References
- 1. Huang C, Wang Y, Li X, Ren L, Zhao J, Hu Y, et al. Clinical features of patients infected with 2019 novel coronavirus in Wuhan, China. Lancet 2020; 395:497e506.
- 2.
World Health Organization. WHO Director-General’s opening remarks at the media briefing onCOVID-19e11 March 2020.Geneva: WHO; 2020. https://www.who.int/dg/speeches/Detail/who-director-general-s-opening-remarks-at-the-mediabriefing-on-covid-19-11-march-2020 [last accessed April 2020].
- 3.
Worldometer. Coronavirus cases. https://www.worldometers.info/coronavirus/coronavirus-cases/#daily-cases [last accessed October 2020].
- 4. Masters PS. Coronavirus genomic RNA packaging. Virology. 2019;537(August):198–207. pmid:31505321
- 5.
World Health Organization. Coronavirus disease (COVID-19) advice for the public. Basic protective measures against the new coronavirus. https://www.who.int/emergencies/diseases/novel-coronavirus-2019/advice-for-public. Accessed August 12, 2020
- 6. Hoe Gan W, Wah Lim J, Koh D. Preventing intra-hospital infection and transmission of COVID-19 in healthcare workers. Saf Health Work 2020. https://doi.org/10.1016/j.shaw.2020.03.001.
- 7. Bhagavathula AS, Aldhaleei WA, Rahmani J, Mahabadi MA, Bandari DK. Novel coronavirus (COVID-19) knowledge and perceptions: a survey on healthcare workers. MedRxiv 2020.
- 8. Wu Z, McGoogan JM. Characteristics of and important lessons from the coronavirus disease 2019 (COVID-19) outbreak in China: summary of a report of 72314 cases from the Chinese Center for Disease Control and Prevention. JAMA 2020 Feb 24 [online ahead of print].
- 9. McEachan R, Taylor N, Harrison R, Lawton R, Gardner P, Conner M. Meta-analysis of the reasoned action approach (RAA) to understanding health behaviors. Ann Behav Med 2016;50: 592e612. pmid:27169555
- 10.
WHO https://www.who.int/news/item/17-09-2020-keep-health-workers-safe-to-keep-patients-safe-who
- 11. Teferi SC. A Review on Knowledge, Attitude, and Practice during the COVID-19 Pandemic in Ethiopia. Journal of Biomedical Research & Environmental Sciences. 2020 Aug 29;6(8):040–4.
- 12.
PRISMA. PRISMA transparent reporting of systematic reviews and meta-analyses. 2011. http://www.prisma-statement.org/documents/PRISMA-P. Accessed 1 Feb 2019.
- 13.
Joanna Briggs Institute. Critical Appraisal Tools Australia: The University of Adelaide; 2018. http://joannabriggs.org/research/criticalappraisal-tools.html. Accessed 1 Feb 2019
- 14. Egger M., Smith G.D., Schneider M., Minder C., Bias in meta-analysis detected by a simple, graphical test. BMJ. 1997; 315(7109):629–34. pmid:9310563
- 15.
Egger M., Smith G.D., Altman D.G., Systematic review in health care; Meta-Analysis in context, BMJ publishing group, London, 2001
- 16. Borenstein M, Hedges LV, Higgins J, Rothstein HR. A basic introduction to fixed effect and random-effects models for meta-analysis. Res Synthesis Methods. 2010; 1(2):97–111. pmid:26061376
- 17. Kassie BA, Adane A, Tilahun YT, Kassahun EA, Ayele AS, Belew AK. Knowledge and attitude towards COVID-19 and associated factors among health care providers in Northwest Ethiopia. PloS one. 2020 Aug 28;15(8):e0238415.(1) pmid:32857811
- 18. Asemahagn MA. Factors determining the knowledge and prevention practice of healthcare workers towards COVID-19 in Amhara region, Ethiopia: a cross-sectional survey. Tropical medicine and health. 2020 Dec;48(1):1–1. pmid:32839649
- 19. Feleke DG, Tassew SF, Chanie ES. Assessment of Knowledge, Attitude and Associated Factors toward COVID-19 among Nurses Who Work in South Gondar Zone, Hospitals, Northwest Ethiopia 2020, Institution-based cross-sectional Study.
- 20. Tesfaye ZT, Yismaw MB, Negash Z, Ayele AG. COVID-19-Related Knowledge, Attitude and Practice Among Hospital and Community Pharmacists in Addis Ababa, Ethiopia. Integrated Pharmacy Research & Practice. 2020;9:105. pmid:32904494
- 21. Tamire AH, Tamire AH, Legesse TK. Original article knowledge, attitudes, and practices towards coronavirus disease -19 among health professionals in addis ababa. 2020; Ethiop Med J, 2020, Vol. 58, No. 4
- 22. Tsegaye D, Shuremu M, Oljira D, Dubale S, Befekadu G, Bidira K. Knowledge and preventive practices towards Covid-19 and associated factors among healthcare workers in selected health facilities of Illu Aba Bor and Buno Bedelle Zones, Southwest Ethiopia.
- 23. Tadesse DB, Gebrewahd GT, Demoz GT. Knowledge, Attitude, Practice and Psychological response toward COVID-19 among Nurses during the COVID-19 outbreak in Northern Ethiopia, 2020.
- 24. Mersha A, Shibiru S, Girma M, Ayele G, Bante A, Kassa M, et al. Health professionals practice and associated factors towards precautionary measures for COVID-19 pandemic in public health facilities of Gamo zone, southern Ethiopia: a cross-sectional study. medRxiv. 2020 Jan 1.
- 25. Jamie AH. KNOWLEDGE, ATTITUDE AND PRACTICE OF HEALTHCARE WORKERS TOWARDS NOVEL CORONA VIRUS (COVID-19) IN JUGAL HOSPITAL, HARARI REGIONAL STATE, ETHIOPIA. Public Health of Indonesia. 2020 Sep 15;6(3):72–7.
- 26. Jemal B, Ferede ZA, Mola S, Hailu S, Abiy S, Wolde GD, et al. Knowledge, attitude and practice of healthcare workers towards COVID-19 and its prevention in Ethiopia: a multicenter study.
- 27. Girma S, Alenko A, Agenagnew L. Knowledge and Precautionary Behavioral Practice Toward COVID-19 Among Health Professionals Working in Public University Hospitals in Ethiopia: A Web-Based Survey. Risk Management and Healthcare Policy. 2020;13:1327. pmid:32922101
- 28.
FMOH. National Comprehensive COVID-19 management Handbook. Ethiopian Federal Ministry of Health April 2020
- 29. Chen Y, Tong X, Wang J, Huang W, Yin S, Huang R, et al. High SARS-CoV-2 Antibody Prevalence among Healthcare Workers Exposed to COVID-19 Patients. Journal of Infection. 2020. pmid:32504745
- 30. Bhagavathula AS, Aldhaleei WA, Rahmani J, Khubchandani J. Knowledge, Attitude, Perceptions and Practice towards COVID-19: A systematic review and Meta-analysis. medRxiv. 2020 Jan 1.